/**************************************************************************************************/
/** \defgroup Core_Register_gr Core Register Access
\brief Functions to access the Cortex-M core registers.
\details
  The following functions provide access to Cortex-M core registers. 

  @{ 
*/


/**************************************************************************************************/
/** \brief  Read the CONTROL register
    \details
    The function reads the CONTROL register value using the instruction \b MRS. 
    \n\n
    The CONTROL register controls the stack used and the privilege level for software execution
    when the processor is in thread mode and, if implemented, indicates whether the FPU state is
    active. This register uses the following bits:
    \n
    - \b CONTROL[2] [only Cortex-M4 and Cortex-M7]
        - =0 FPU not active
        - =1 FPU active
        \n\n
    - \b CONTROL[1] 
        - =0 In handler mode - MSP is selected. No alternate stack possible for handler mode.
        - =0 In thread mode - Default stack pointer MSP is used.
        - =1 In thread mode - Alternate stack pointer PSP is used.
        \n\n
    - \b CONTROL[0] [not Cortex-M0]
        - =0 In thread mode and privileged state.
        - =1 In thread mode and user state.
     
    \returns    CONTROL register value
    
    \remarks    
            - The processor can be in user state or privileged state when running in thread mode.
            - Exception handlers always run in privileged state.
            - On reset, the processor is in thread mode with privileged access  rights.
    
    \sa     
            - \ref __set_CONTROL; CONTROL_Type 
            - \ref ref_man_sec
 */
uint32_t __get_CONTROL(void);


/**************************************************************************************************/
/** \brief  Set the CONTROL Register
    \details 
    The function sets the CONTROL register value using the instruction \b MSR. 
    \n\n
    The CONTROL register controls the stack used and the privilege level for software execution
    when the processor is in thread mode and, if implemented, indicates whether the FPU state is
    active. This register uses the following bits:
    \n
    - \b CONTROL[2] [only Cortex-M4 and Cortex-M7]
        - =0 FPU not active
        - =1 FPU active
        \n\n
    - \b CONTROL[1] 
        - Writeable only when the processor is in thread mode and privileged state (CONTROL[0]=0).
        - =0 In handler mode - MSP is selected. No alternate stack pointer possible for handler mode.
        - =0 In thread mode - Default stack pointer MSP is used.
        - =1 In thread mode - Alternate stack pointer PSP is used.
        \n\n
    - \b CONTROL[0] [not writeable for Cortex-M0]
        - Writeable only when the processor is in privileged state.
        - Can be used to switch the processor to user state (thread mode).
        - Once in user state, trigger an interrupt and change the state to privileged in the 
        exception handler (the only way).
        - =0 In thread mode and privileged state.
        - =1 In thread mode and user state.

     
    \param [in] control  CONTROL register value to set    
    
    \remarks    
            - The processor can be in user state or privileged state when running in thread mode.
            - Exception handlers always run in privileged state.
            - On reset, the processor is in thread mode with privileged access  rights.

    \sa     
            - \ref __get_CONTROL; __set_PSP; __set_MSP; CONTROL_Type 
            - \ref ref_man_sec
*/
void __set_CONTROL(uint32_t control);


/**************************************************************************************************/
/** \brief  Read the IPSR register
    \details 
    The function reads the Interrupt Program Status Register (IPSR) using the instruction \b MRS. 
    \n\n
    The ISPR contains the exception type number of the current Interrupt Service Routine (ISR). 
    Each exception has an associated unique IRQn number. The following bits are used:
    
    - \b ISR_NUMBER (IPSR[8:0])
        - = 0 Thread mode
        - = 1 Reserved
        - = 2 NMI
        - = 3 HardFault
        - = 4 MemManage
        - = 5 BusFault
        - = 6 UsageFault
        - = 7 SecureFault
        - = 8-10  Reserved
        - = 11 SVC
        - = 12 Reserved for Debug
        - = 13 Reserved
        - = 14 PendSV
        - = 15 SysTick
        - = 16 IRQ0
        - ...
        - = n+15 IRQ(n-1)

    \returns    ISPR register value

    \remarks    
            - This register is read-only.

    \sa     
            - \ref __get_xPSR; IPSR_Type
            - \ref NVIC_gr
            - \ref ref_man_sec
*/
uint32_t __get_IPSR(void);


/**************************************************************************************************/
/** \brief  Read the APSR register
    \details
    The function reads the Application Program Status Register (APSR) using the instruction \b MRS.
    \n\n
    The APSR contains the current state of the condition flags from instructions executed previously.
    The APSR is essential for controlling conditional branches. The following flags are used:
    
    - \b N (APSR[31]) (Negative flag)
        - =1 The instruction result has a negative value (when interpreted as signed integer).
        - =0 The instruction result has a positive value or equal zero.
    \n\n
    - \b Z (APSR[30]) (Zero flag)
        - =1 The instruction result is zero. Or, after a compare instruction, when the two values
            are the same.
    \n\n
    - \b C (APSR[29]) (Carry or borrow flag)
        - =1 For unsigned additions, if an unsigned overflow occurred.
        - =<i>inverse of borrow output status</i> For unsigned subtract operations.
    \n\n
    - \b V (APSR[28]) (Overflow flag)
        - =1 A signed overflow occurred (for signed additions or subtractions).
    \n\n
    - \b Q (APSR[27]) (DSP overflow or saturation flag) [not Cortex-M0]
        - This flag is a \em sticky flag. Saturating and certain multiplying instructions can set the
        flag, but cannot clear it. 
        - =1 When saturation or an overflow occurred.
    \n\n
    - \b GE (APSR[19:16]) (Greater than or Equal flags) [not Cortex-M0]
        - Can be set by the parallel add and subtract instructions.
        - Are used by the <kbd>SEL</kbd> instruction to perform byte-based selection from two registers.
    
    
    \returns    APSR register value

    \remarks    
            - Some instructions update all flags; some instructions update a subset of the flags. 
            - If a flag is not updated, the original value is preserved. 
            - Conditional instructions that are not executed have no effect on the flags.
            - The CMSIS does not provide a function to update this register.

    \sa     
            - \ref __get_xPSR; APSR_Type 
            - \ref ref_man_sec

 */
uint32_t __get_APSR(void);


/**************************************************************************************************/
/** \brief  Read the xPSR register 
    \details 
    The function reads the combined Program Status Register (xPSR) using the instruction \b MRS. 
    \n\n
    xPSR provides information about program execution and the APSR flags. It consists of the 
    following PSRs:
    \li Application Program Status Register (APSR)
    \li Interrupt Program Status Register (IPSR)
    \li Execution Program Status Register (EPSR)
    
    In addition to the flags described in \ref __get_APSR and \ref __get_IPSR, the register provides 
    the following flags:
    - \b IT (xPSR[26:25]) (If-Then condition instruction)
        - Contains up to four instructions following an IT instruction. 
        - Each instruction in the block is conditional. 
        - The conditions for the instructions are either all the same, or some can be the inverse 
        of others.
    \n\n
    - \b T (xPSR[24]) (Thumb bit) 
        - =1 Indicates that that the processor is in Thumb state. 
        - =0 Attempting to execute instructions when the T bit is 0 results in a fault or lockup. 
        - The conditions for the instructions are either all the same, or some can be the inverse 
        of others.
    
    \returns    xPSR register value 
    
    \remarks
        - The CMSIS does not provide functions that access EPSR.

    \sa     
            - \ref __get_APSR; __get_IPSR; xPSR_Type
            - \ref ref_man_sec
    
 */
uint32_t __get_xPSR(void);


/**************************************************************************************************/
/** \brief  Read the PSP register
    \details 
    The function reads the Process Stack Pointer (PSP) value using the instruction \b MRS.
    \n\n
    Physically two different stack pointers (SP) exist: 
    - The Main Stack Pointer (MSP) is the default stack pointer after reset. It is also used when 
    running exception handlers (handler mode).
    - The Process Stack Pointer (PSP), which can be used only in thread mode. 
    
    Register R13 banks the SP. The SP selection is determined by the bit[1] of the CONTROL register: 
    - =0 MSP is the current stack pointer. This is also the default SP. The initial value is loaded 
    from the first 32-bit word of the vector table from the program memory.
    - =1 PSP is the current stack pointer. The initial value is undefined. 
  
    \returns    PSP register value
        
    \remarks
        - Only one of the two SPs is visible at a time.
        - For many applications, the system can completely rely on the MSP.
        - The PSP is normally used in designs with an OS where the stack memory for OS Kernel must 
        be separated from the application code.  

    \sa 
        - \ref __set_PSP; __get_MSP; __get_CONTROL
        - \ref ref_man_sec

    
 */
uint32_t __get_PSP(void);


/**************************************************************************************************/
/** \brief  Set the PSP register
    \details
    The function sets the Process Stack Pointer (PSP) value using the instruction \b MSR.
    \n\n
    Physically two different stack pointers (SP) exist: 
    - The Main Stack Pointer (MSP) is the default stack pointer after reset. It is also used when 
    running exception handlers (handler mode).
    - The Process Stack Pointer (PSP), which can be used only in thread mode. 
    
    Register R13 banks the SP. The SP selection is determined by the bit[1] of the CONTROL register: 
    - =0 MSP is the current stack pointer. This is also the default SP. The initial value is loaded 
    from the first 32-bit word of the vector table from the program memory.
    - =1 PSP is the current stack pointer. The initial value is undefined. 
    
    \param [in]    topOfProcStack  PSP value to set
        
    \remarks
        - Only one of the two SPs is visible at a time.
        - For many applications, the system can completely rely on the MSP.
        - The PSP is normally used in designs with an OS where the stack memory for OS Kernel must 
        be separated from the application code.  
        
    \sa 
        - \ref __get_PSP; __set_MSP; __set_CONTROL
        - \ref ref_man_sec
 */
void __set_PSP(uint32_t topOfProcStack);


/**************************************************************************************************/
/** \brief  Read the MSP register
    \details 
    The function reads the Main Stack Pointer (MSP) value using the instruction \b MRS.
    \n\n
    Physically two different stack pointers (SP) exist: 
    - The Main Stack Pointer (MSP) is the default stack pointer after reset. It is also used when 
    running exception handlers (handler mode).
    - The Process Stack Pointer (PSP), which can be used only in thread mode. 
    
    Register R13 banks the SP. The SP selection is determined by the bit[1] of the CONTROL register: 
    - =0 MSP is the current stack pointer. This is also the default SP. The initial value is loaded 
    from the first 32-bit word of the vector table from the program memory.
    - =1 PSP is the current stack pointer. The initial value is undefined. 
    
    \returns    MSP Register value 

    \remarks
        - Only one of the two SPs is visible at a time.
        - For many applications, the system can completely rely on the MSP.
        - The PSP is normally used in designs with an OS where the stack memory for OS Kernel must 
        be separated from the application code.  
        
    \sa 
        - \ref __set_MSP; __get_PSP; __get_CONTROL
        - \ref ref_man_sec

 */
uint32_t __get_MSP(void);


/**************************************************************************************************/
/** \brief  Set the MSP register
    \details 
    The function sets the Main Stack Pointer (MSP) value using the instruction \b MSR.
    \n\n
    Physically two different stack pointers (SP) exist: 
    - The Main Stack Pointer (MSP) is the default stack pointer after reset. It is also used when 
    running exception handlers (handler mode).
    - The Process Stack Pointer (PSP), which can be used only in thread mode. 
    
    Register R13 banks the SP. The SP selection is determined by the bit[1] of the CONTROL register: 
    - =0 MSP is the current stack pointer. This is also the default SP. The initial value is loaded 
    from the first 32-bit word of the vector table from the program memory.
    - =1 PSP is the current stack pointer. The initial value is undefined. 
    
    \param [in]    topOfMainStack  MSP value to set

    \remarks
        - Only one of the two SPs is visible at a time.
        - For many applications, the system can completely rely on the MSP.
        - The PSP is normally used in designs with an OS where the stack memory for OS Kernel must 
        be separated from the application code.  
        
    \sa 
        - \ref __get_MSP; __set_PSP; __set_CONTROL
        - \ref ref_man_sec

 */
void __set_MSP(uint32_t topOfMainStack);


/**************************************************************************************************/
/** \brief  Read the PRIMASK register bit 
    \details 
    The function reads the Priority Mask register (PRIMASK) value using the instruction \b MRS. 
    \n\n
    PRIMASK is a 1-bit-wide interrupt mask register. When set,
    it blocks all interrupts apart from the non-maskable interrupt (NMI) and the hard fault exception.
    The PRIMASK prevents activation of all exceptions with configurable priority.

    \returns    PRIMASK register value
                - =0 no effect
                - =1 prevents the activation of all exceptions with configurable priority
           
    \sa 
        - \ref __set_PRIMASK; __get_BASEPRI; __get_FAULTMASK
        - \ref ref_man_sec                    
                    
 */
uint32_t __get_PRIMASK(void);


/**************************************************************************************************/
/** \brief  Set the Priority Mask bit
    \details 
    The function sets the Priority Mask register (PRIMASK) value using the instruction \b MSR. 
    \n\n
    PRIMASK is a 1-bit-wide interrupt mask register. When set,
    it blocks all interrupts apart from the non-maskable interrupt (NMI) and the hard fault exception.
    The PRIMASK prevents activation of all exceptions with configurable priority.

    \param [in]    priMask  Priority Mask
                    - =0 no effect
                    - =1 prevents the activation of all exceptions with configurable priority

    \remarks
        - When set, PRIMASK effectively changes the current priority level to 0. 
        This is the highest programmable level.
        - When set and a fault occurs, the hard fault handler will be executed.
        - Useful for temporarily disabling all interrupts for timing critical tasks. 
        - Does not have the ability to mask BusFault or bypass MPU.

    \sa 
        - \ref __get_PRIMASK; __set_BASEPRI; __set_FAULTMASK
        - \ref ref_man_sec                    

 */
void __set_PRIMASK(uint32_t priMask);
 

/**************************************************************************************************/
/** \brief  Read the BASEPRI register [not for Cortex-M0, Cortex-M0+, or SC000]
    \details 
    The function returns the Base Priority Mask register (BASEPRI) using the instruction \b MRS. 
    \n\n
    BASEPRI defines the minimum priority for exception processing. When BASEPRI is set to a non-zero 
    value, it prevents the activation of all exceptions with the same or lower priority level as 
    the BASEPRI value.
    
    \returns    BASEPRI register value

    \remarks    
        - Not for Cortex-M0, Cortex-M0+, or SC000.
                    
    \sa 
        - \ref __set_BASEPRI;  __set_BASEPRI_MAX; __get_FAULTMASK; __get_PRIMASK
        - \ref ref_man_sec

    */
uint32_t __get_BASEPRI(void);


/**************************************************************************************************/
/** \brief  Set the BASEPRI register [not for Cortex-M0, Cortex-M0+, or SC000]
    \details 
    The function sets the Base Priority Mask register (BASEPRI) value using the instruction \b MSR.
    \n\n
    BASEPRI defines the minimum priority for exception processing. 
    When BASEPRI is set to a non-zero value, it prevents the activation of all exceptions with the 
    same or lower priority level as the BASEPRI value.
    
    \param [in]    basePri  BASEPRI value to set

    \remarks    
        - Not for Cortex-M0, Cortex-M0+, or SC000.
        - Cannot be set in user state.
        - Useful for changing the masking level or disabling the masking.

    \sa 
        - \ref __get_BASEPRI;  __set_BASEPRI_MAX; __set_FAULTMASK; __set_PRIMASK
        - \ref ref_man_sec
    
 */
void __set_BASEPRI(uint32_t basePri); 
 
 
/**************************************************************************************************/
/** \brief  Increase the BASEPRI register [not for Cortex-M0, Cortex-M0+, or SC000]
    \details 
    The function only increases the Base Priority Mask register (BASEPRI) value using the instruction \b MSR.
	The value is set only if BASEPRI masking is disabled, or the new value increases the BASEPRI priority level.
    \n\n
    BASEPRI defines the minimum priority for exception processing. 
        
    \param [in]    basePri  BASEPRI value to set

    \remarks    
        - Not for Cortex-M0, Cortex-M0+, or SC000.
        - Cannot be set in user state.
        - Useful for increasing the masking level.
        - Has no effect when \em basePri is lower than the current value of BASEPRI.
        - Use \ref __set_BASEPRI to lower the Base Priority Mask register.

    \sa 
        - \ref __set_BASEPRI; __get_BASEPRI; __set_FAULTMASK; __set_PRIMASK
        - \ref ref_man_sec
    
 */
void __set_BASEPRI_MAX(uint32_t basePri); 


/**************************************************************************************************/
/** \brief  Read the FAULTMASK register [not for Cortex-M0, Cortex-M0+, or SC000]
    \details 
    The function reads the Fault Mask register (FAULTMASK) value using the instruction \b MRS. 
    \n\n
    FAULTMASK prevents activation of all exceptions except for the Non-Maskable Interrupt (NMI).

    \returns    FAULTMASK register value

    \remarks    
        - not for Cortex-M0, Cortex-M0+, or SC000.
        - Is cleared automatically upon exiting the exception handler, except when returning 
        from the NMI handler.

    \sa 
        - \ref __set_FAULTMASK; __get_BASEPRI; __get_PRIMASK 
        - \ref ref_man_sec
 */
uint32_t __get_FAULTMASK(void);


/**************************************************************************************************/
/** \brief  Set the FAULTMASK register [not for Cortex-M0, Cortex-M0+, or SC000]
    \details 
    The function sets the Fault Mask register (FAULTMASK) value using the instruction \b MSR.
    \n\n
    FAULTMASK prevents activation of all exceptions except for Non-Maskable Interrupt (NMI).
    FAULTMASK can be used to escalate a configurable fault handler (BusFault, usage fault, or 
    memory management fault) to hard fault level without invoking a hard fault. This allows the 
    fault handler to pretend to be the hard fault handler, with the ability to:
    -# <b>Mask BusFault</b> by setting the BFHFNMIGN in the Configuration Control register.
    It can be used to test the bus system without causing a lockup. 
    -# <b>Bypass the MPU</b>, allowing accessing the MPU protected memory location without 
    reprogramming the MPU to just carry out a few transfers for fixing faults.

    \param [in]    faultMask  FAULTMASK register value to set 

    \remarks    
        - not for Cortex-M0, Cortex-M0+, or SC000.
        - Is cleared automatically upon exiting the exception handler, except when returning 
        from the NMI handler.
        - When set, it changes the effective current priority level to -1, so that even the hard
        fault handler is blocked.
        - Can be used by fault handlers to change their priority to -1 to have access to some 
        features for hard fault exceptions (see above).
        - When set, lockups can still be caused by incorrect or undefined instructions, or by using
        SVC in the wrong priority level.

    \sa 
        - \ref __get_FAULTMASK; __set_BASEPRI; __set_PRIMASK 
        - \ref ref_man_sec
 */
void __set_FAULTMASK(uint32_t faultMask);


/**************************************************************************************************/
/** \brief  Read the FPSCR register [only Cortex-M4 and Cortex-M7]
    \details 
    The function reads the Floating-Point Status Control Register (FPSCR) value. 
    \n\n
    FPSCR provides all necessary User level controls of the floating-point system. 
        
    \returns    
            - FPSCR register value, when __FPU_PRESENT=1
            - =0, when __FPU_PRESENT=0

    \remarks
            - Only for Cortex-M4 and Cortex-M7.
                
    \sa 
            - \ref __set_FPSCR
            - \ref ref_man_sec
                    
 */
uint32_t __get_FPSCR(void);


/**************************************************************************************************/
/** \brief  Set the FPSC register [only for Cortex-M4 and Cortex-M7]
    \details 
    The function sets the Floating-Point Status Control Register (FPSCR) value. 
    \n\n
    FPSCR provides all necessary User level control of the floating-point system. 
    \n
    - \b N (FPSC[31]) (Negative flag)
        - =1 The instruction result has a negative value (when interpreted as signed integer).
        - =0 The instruction result has a positive value or equal zero.
    \n\n
    - \b Z (FPSC[30]) (Zero flag)
        - =1 The instruction result is zero. Or, after a compare instruction, when the two values
            are the same.
    \n\n
    - \b C (FPSC[29]) (Carry or borrow flag)
        - =1 For unsigned additions, if an unsigned overflow occurred.
        - =<i>inverse of borrow output status</i> For unsigned subtract operations.
    \n\n
    - \b V (FPSC[28]) (Overflow flag)
        - =1 A signed overflow occurred (for signed additions or subtractions).
    \n\n
    - \b AHP (FPSC[26]) (Alternative half-precision flag)
        - =1 Alternative half-precision format selected.
        - =0 IEEE half-precision format selected.
    \n\n
    - \b DN (FPSC[25]) (Default NaN mode control flag)
        - =1 Any operation involving one or more NaNs returns the Default NaN.
        - =0 NaN operands propagate through to the output of a floating-point operation.
    \n\n
    - \b FZ (FPSC[24]) (Flush-to-zero mode control flag)
        - =1 Flush-to-zero mode enabled.
        - =0 Flush-to-zero mode disabled. Behavior of the floating-point system is fully 
        compliant with the IEEE 754 standard.
    \n\n
    - \b RMode (FPSC[23:22]) (Rounding Mode control flags)
        - =0b00 Round to Nearest (RN) mode.
        - =0b01 Round towards Plus Infinity (RP) mode.
        - =0b10 Round towards Minus Infinity (RM) mode.
        - =0b11 Round towards Zero (RZ) mode.
        - The specified rounding mode is used by almost all floating-point instructions.
    \n\n
    - \b IDC (FPSC[7]) (Input Denormal cumulative exception flags)
        - See Cumulative exception bits (FPSC[4:0]).
    \n\n
    - \b IXC (FPSC[4]) (Inexact cumulative exception flag)
        - =1 Exception occurred. 
        - =0 Value has to be set explicitly. 
        - Flag is not cleared automatically.
    \n\n
    - \b UFC (FPSC[3]) (Underflow cumulative exception flag)
        - =1 Exception occurred. 
        - =0 Value has to be set explicitly. 
        - Flag is not cleared automatically.
    \n\n
    - \b OFC (FPSC[2]) (Overflow cumulative exception flag)
        - =1 Exception occurred. 
        - =0 Value has to be set explicitly. 
        - Flag is not cleared automatically.
    \n\n
    - \b DZC (FPSC[1]) (Division by Zero cumulative exception flag)
        - =1 Exception occurred. 
        - =0 Value has to be set explicitly. 
        - Flag is not cleared automatically.
    \n\n
    - \b IOC (FPSC[0]) (Invalid Operation cumulative exception flag)
        - =1 Exception occurred. 
        - =0 Value has to be set explicitly. 
        - Flag is not cleared automatically.
        
    \param [in]    fpscr  FPSCR value to set

    \remarks
            - Only for Cortex-M4 and Cortex-M7.
            - The variable \b __FPU_PRESENT has to be set to 1.
    
    \sa 
            - \ref __get_FPSCR
            - \ref ref_man_sec
 */
void __set_FPSCR(uint32_t fpscr);


/**************************************************************************************************/
/** \brief  Globally enables interrupts and configurable fault handlers
    \details
    The function enables interrupts and all configurable fault handlers by clearing PRIMASK.
    The function uses the instruction <b>CPSIE i</b>.

    \remarks
            - Can be executed in privileged mode only. 
            
    \sa 
        - \ref __disable_irq; __set_BASEPRI; __set_CONTROL; __set_PRIMASK
 */
void __enable_irq(void);


/**************************************************************************************************/
/** \brief  Globally disables interrupts and configurable fault handlers
    \details 
    The function disables interrupts and all configurable fault handlers by setting PRIMASK. 
    The function uses the instruction <b>CPSID i</b>.

    \remarks
        - Can be executed in privileged mode only. 
        - An interrupt can enter pending state even if it is disabled. Disabling an interrupt 
        only prevents the processor from taking that interrupt.

    \sa 
        - \ref __enable_irq;  __set_BASEPRI; __set_CONTROL; __set_PRIMASK
 */
void __disable_irq(void);


/**************************************************************************************************/
/** \brief  Enables interrupts and all fault handlers [not for Cortex-M0, Cortex-M0+, or SC000]
    \details 
    The function enables interrupts and all fault handlers by clearing FAULTMASK.
    The function uses the instruction <b>CPSIE f</b>.

    \remarks
            - not for Cortex-M0, Cortex-M0+, or SC000.
            - Can be executed in privileged mode only. 
    
    \sa 
        - \ref __disable_fault_irq; __set_BASEPRI; __set_CONTROL; __set_FAULTMASK
 */
 void __enable_fault_irq(void);


/**************************************************************************************************/
/** \brief  Disables interrupts and all fault handlers [not for Cortex-M0, Cortex-M0+, or SC000]
    \details 
    The function disables interrupts and all fault handlers by setting FAULTMASK.
    The function uses the instruction <b>CPSID f</b>.

    \remarks
        - not for Cortex-M0, Cortex-M0+, or SC000.
        - Can be executed in privileged mode only. 
        - An interrupt can enter pending state even if it is disabled. Disabling an interrupt 
        only prevents the processor from taking that interrupt.

    \sa 
        - \ref __enable_fault_irq; __set_BASEPRI; __set_CONTROL; __set_FAULTMASK
 */
void __disable_fault_irq(void);

/**
\cond (ARMv8M)
*/

/**
  \brief   Get Process Stack Pointer Limit
  Devices without Armv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
  Stack Pointer Limit register hence zero is returned always in non-secure
  mode.

  \details Returns the current value of the Process Stack Pointer Limit (PSPLIM).
  \return               PSPLIM Register value
  \note    Only available for Armv8-M Architecture. 
 */
uint32_t __get_PSPLIM(void);

/**
  \brief   Set Process Stack Pointer Limit
  Devices without Armv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
  Stack Pointer Limit register hence the write is silently ignored in non-secure
  mode.

  \details Assigns the given value to the Process Stack Pointer Limit (PSPLIM).
  \param [in]    ProcStackPtrLimit  Process Stack Pointer Limit value to set
  \note    Only available for Armv8-M Architecture. 
 */
void __set_PSPLIM(uint32_t ProcStackPtrLimit);

/**
  \brief   Get Main Stack Pointer Limit
  Devices without Armv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
  Stack Pointer Limit register hence zero is returned always in non-secure
  mode.

  \details Returns the current value of the Main Stack Pointer Limit (MSPLIM).
  \return               MSPLIM Register value
  \note    Only available for Armv8-M Architecture. 
 */
uint32_t __get_MSPLIM(void);

/**
  \brief   Set Main Stack Pointer Limit
  Devices without Armv8-M Main Extensions (i.e. Cortex-M23) lack the non-secure
  Stack Pointer Limit register hence the write is silently ignored in non-secure
  mode.

  \details Assigns the given value to the Main Stack Pointer Limit (MSPLIM).
  \param [in]    MainStackPtrLimit  Main Stack Pointer Limit value to set
  \note    Only available for Armv8-M Architecture. 
 */
__set_MSPLIM(uint32_t MainStackPtrLimit);

/**
\endcond
*/

/** @} */ /** end of Core_Register_gr **/
